US9274276B2 - Light confining devices using all-dielectric metamaterial cladding - Google Patents
Light confining devices using all-dielectric metamaterial cladding Download PDFInfo
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- US9274276B2 US9274276B2 US14/175,606 US201414175606A US9274276B2 US 9274276 B2 US9274276 B2 US 9274276B2 US 201414175606 A US201414175606 A US 201414175606A US 9274276 B2 US9274276 B2 US 9274276B2
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- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B6/00—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings
- G02B6/10—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings of the optical waveguide type
- G02B6/12—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings of the optical waveguide type of the integrated circuit kind
- G02B6/122—Basic optical elements, e.g. light-guiding paths
- G02B6/1225—Basic optical elements, e.g. light-guiding paths comprising photonic band-gap structures or photonic lattices
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- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B1/00—Optical elements characterised by the material of which they are made; Optical coatings for optical elements
- G02B1/002—Optical elements characterised by the material of which they are made; Optical coatings for optical elements made of materials engineered to provide properties not available in nature, e.g. metamaterials
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- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B27/00—Optical systems or apparatus not provided for by any of the groups G02B1/00 - G02B26/00, G02B30/00
- G02B27/01—Head-up displays
- G02B27/017—Head mounted
- G02B27/0176—Head mounted characterised by mechanical features
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- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B6/00—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings
- G02B6/02—Optical fibres with cladding with or without a coating
- G02B6/0229—Optical fibres with cladding with or without a coating characterised by nanostructures, i.e. structures of size less than 100 nm, e.g. quantum dots
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- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B6/00—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings
- G02B6/02—Optical fibres with cladding with or without a coating
- G02B6/02295—Microstructured optical fibre
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- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B6/00—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings
- G02B6/02—Optical fibres with cladding with or without a coating
- G02B6/02295—Microstructured optical fibre
- G02B6/023—Microstructured optical fibre having different index layers arranged around the core for guiding light by reflection, i.e. 1D crystal, e.g. omniguide
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B82—NANOTECHNOLOGY
- B82Y—SPECIFIC USES OR APPLICATIONS OF NANOSTRUCTURES; MEASUREMENT OR ANALYSIS OF NANOSTRUCTURES; MANUFACTURE OR TREATMENT OF NANOSTRUCTURES
- B82Y20/00—Nanooptics, e.g. quantum optics or photonic crystals
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- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B6/00—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings
- G02B6/10—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings of the optical waveguide type
- G02B6/12—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings of the optical waveguide type of the integrated circuit kind
- G02B2006/12035—Materials
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- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B6/00—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings
- G02B6/10—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings of the optical waveguide type
- G02B6/12—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings of the optical waveguide type of the integrated circuit kind
- G02B2006/12035—Materials
- G02B2006/12061—Silicon
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10S—TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10S977/00—Nanotechnology
- Y10S977/902—Specified use of nanostructure
- Y10S977/932—Specified use of nanostructure for electronic or optoelectronic application
Definitions
- the present disclosure is related to the field of optical light confining devices such as resonators and waveguides, and more particularly to optical waveguides for use in integrated photonic circuits.
- Light has a characteristic size, the wavelength, which sets a limit to all conventional optical device sizes, especially waveguides and resonators.
- This limit called the diffraction limit is a fundamental obstacle and is defined as the size of the optical mode in a resonator or waveguide.
- the value is given by ( ⁇ /2n core ) ⁇ 3 in a 3D geometry, ( ⁇ /2n core ) ⁇ 2 in a 2D geometry and ( ⁇ /2n core ) ⁇ 1 in a 1D geometry.
- ⁇ /2n core is the wavelength in free space divided by twice the value of the refractive index of the core of the waveguide or resonator. The ability to overcome this limit is key to future photonic integrated circuits combining nano-scale electrical and micron-scale optical signals.
- SPP surface plasmon polariton
- IMI metal strip
- M ⁇ metal metal strip
- V-groove and wedge plasmon are an excellent candidates for relatively long range propagation and sub-diffraction confinement, however excitation and detection of these modes as well as interfacing with existing silicon waveguide technology are a major challenge.
- hybrid dielectric-plasmonic waveguides have emerged that confine light in a high index gap above metals reducing the field penetration in the metal thus allowing for increased propagation length.
- Another alternative is an epsilon-near-zero metamaterial waveguide which allows modes to tunnel through subwavelength size structures.
- the above mentioned sub-diffraction plasmonic structures cannot guide light more than a few microns.
- the dissipated energy leads to thermal issues which are especially significant in miniaturized circuits hindering dense photonic integration.
- the waveguides according to the invention include all-dielectric metamaterial claddings that can strongly confine light inside low-index dielectric waveguides.
- transforming optical momentum for controlling evanescent waves can be used. These transformations lead to a medium that supports total internal reflection and simultaneously makes the evanescent field outside the core of the waveguide decay faster.
- These transformations also lead to a class of metamaterials with dual electric and magnetic anisotropy and a very large birefringence which provides an ideal quasi-transverse electromagnetic mode propagation inside a glass core. Magnetism at the telecommunication wavelength is a challenge and strong confinement of the electric energy of a waveguide mode can be achieved with lossless semiconductor metamaterials.
- An optical waveguide having a cladding composed of all-dielectric metamaterials is provided.
- the diffraction limit of light can be surpassed by the use of a new class of metamaterials having a dielectric response that cannot be found in nature, but can be nanofabricated with readily available building blocks. These metamaterials do not have metallic building blocks thereby overcoming the shortcoming related to loss in the prior art.
- the rules of transformation optics can be used to transform optical momentum for controlling evanescent waves. With this class of transformations, it is possible to confine light inside a subwavelength low-index dielectric rod surrounded by metamaterial claddings. This transformation can cause the propagating mode to become close to a transverse electromagnetic (TEM) mode.
- TEM transverse electromagnetic
- a practically achievable all-dielectric metamaterial waveguide can be shown with reduced mode area and increased power confinement in the core for use in dense photonic integration.
- the metamaterial waveguide can dramatically decrease crosstalk between two slab waveguides at infrared wavelengths and, in some embodiments, at the telecommunication optical wavelength (i.e. 1550 nm).
- an optical waveguide for use with electromagnetic signals operating at infrared wavelengths, the optical waveguide including: a core that is substantially transparent at the infrared wavelengths, the core including a longitudinal axis, z, and orthogonal axes, x and y, that are substantially perpendicular to the longitudinal axis, the core having a radius in a plane defined by the x and y axes that is a fraction of the infrared wavelengths; and a metamaterial cladding disposed around the core, the cladding configured to provide quasi-transverse electromagnetic mode propagation of the electromagnetic signals along the z axis of the core.
- a method for routing and transferring information on a photonic integrated circuit using electronic and electromagnetic signals operating at infrared wavelengths, the method including the steps of: providing at least one optical waveguide for use with the signals, the optical waveguide having: a core that is substantially transparent at the infrared wavelengths including a longitudinal axis, z, and further comprising orthogonal axes, x and y, that are substantially perpendicular to the longitudinal axis, the core having a radius in a plane defined by the x and y axes that is a fraction of the infrared wavelengths, and a metamaterial cladding disposed around the core, the cladding configured to provide quasi-transverse electromagnetic mode propagation of the electromagnetic signals along the z axis of the core; placing the optical waveguide on the photonic integrated circuit between an infrared transmitting device and an infrared receiving device; and transmitting the signals between the infrared transmitting and receiving devices.
- the core includes silica.
- the core is a cross-section shape, either circular, square, rectangular, slab, slot, strip or rib.
- the cladding includes a homogeneous anisotropic metamaterial.
- the cladding includes alternating layers of high index semiconductor and a second low index cladding material, wherein each layer of high index semiconductor and the second cladding material is a width that is a fraction of the infrared wavelengths.
- the high index semiconductor in the metamaterial includes Germanium or Silicon.
- the second cladding material includes air, silica, porous silica or silicon.
- the cladding includes nanowires of high index media in a low index material host.
- the nanowires are made of Germanium or Silicon.
- the low index material host for nanowires is made of alumina.
- a photonic integrated device including the optical waveguide as described above.
- the metamaterial cladding according to the invention utilizes no metal, no periodicity, uses anisotropy for total internal reflection and optical momentum transformation and behaves differently from all prior art involving slot waveguides, photonic crystals, plasmonic waveguides.
- An optical waveguide for use with electromagnetic signals operating at infrared wavelengths including a core that is substantially transparent at the infrared wavelengths, the core having a longitudinal axis, z, and orthogonal axes, x and y, that are substantially perpendicular to the longitudinal axis, the core further having a radius in a plane defined by the x and y axes that is a fraction of the infrared wavelengths; and a metamaterial cladding disposed around the core, the cladding anisotropy configured to provide total internal reflection and also increase the decay of evanescent waves, the waveguide providing quasi-transverse electromagnetic mode propagation of the electromagnetic signals along the z axis of the core, provide sub-diffraction confinement of light without loss and strong confinement of light inside the core using metamaterial anisotropy.
- the core may include silica or silicon.
- the core may have a cross-section shape that is one or more from a group consisting of circular, square, rectangular, slab
- the cladding may include a homogeneous lossless anisotropic metamaterial.
- the cladding may have alternating thin film layers of a high index semiconductor and a second low index cladding material, wherein each layer of high index semiconductor and the second cladding material has a width that is a fraction of the infrared wavelengths.
- the high index semiconductor may be Germanium or Silicon.
- the second cladding material may include one or more from a group consisting of air, silica, porous silica and silicon.
- a photonic integrated device may include at least one optical waveguide as set forth above and may use anisotropy to increase decay of evanescent waves.
- the anisotropic cladding can be high index semiconductor rods (e.g. Germanium and Silicon) with a diameter a fraction of the wavelength placed in a low index dielectric host (e.g. Silica, Porous Silica, air, and low index polymers).
- a low index dielectric host e.g. Silica, Porous Silica, air, and low index polymers
- a method for routing and transferring information on a photonic integrated circuit using electronic and electromagnetic signals operating at infrared wavelengths including the steps of: (a) providing at least one optical waveguide for use with the signals, the optical waveguide having: (i) a core that is substantially transparent at the infrared wavelengths, the core having a longitudinal axis, z, and further comprising orthogonal axes, x and y, that are substantially perpendicular to the longitudinal axis, the core having a radius in a plane defined by the x and y axes that is a fraction of the infrared wavelengths, and (ii) a metamaterial cladding disposed around the core, the cladding configured to provide total internal reflection and fast decay of evanescent waves, (iii) a metamaterial cladding with strong anistropy to provide quasi-transverse electromagnetic mode propagation of the electromagnetic signals along the z axis of the core; and (iv) a metamaterial cladding configured to provide loss
- An electromagnetic wave confining device has anisotropic dielectric constants in the cladding providing total internal reflection and fast decay of evanescent waves and provides reduced cross-talk between adjacent devices.
- a matter wave confining device that has anisotropic effective mass providing reduction of tunneling of matter waves.
- An electromagnetic signal confining device utilizing anisotropic metamaterial cladding functioning at Tera-hertz and microwave frequency ranges is provided to provide miniaturization of dielectric antennas and to provide coupling reduction between antenna elements in an antenna array
- a light confining device with a core surrounded by anisotropic metamaterial cladding which uses no metallic components; causes no absorption losses in the metamaterial; provides reduced cross-talk between adjacent waveguides for photonic integration; confines light as a resonator below the diffraction limit for active devices; provides reduction in energy transfer between devices if the core of the waveguides are active; provides increase in the spontaneous emission rate of an emitter if placed inside the core; and provides enhanced nonlinearity if the core is non-linear.
- FIGS. 1A and 1B show X-Y-Z graphs depicting the phenomenon of refraction and reflection of light for: a non-transformed medium in the X-direction; and a transformed medium in the X-direction.
- FIGS. 1C and 1D are drawings depicting light confinement inside a low-index dielectric waveguide with metamaterial claddings according to the invention.
- FIG. 2A displays an electric field of a waveguide according to the invention.
- FIG. 2B displays a mode length comparison.
- FIG. 3A is a cross sectional view and a perspective view of a photonic device having a pair of glass slab waveguides and thin film all-dielectric metamaterials.
- FIG. 3B is a chart showing the comparison of coupling length (cross talk) for conventional slab waveguides, slot waveguides, and transformed cladding waveguides.
- FIG. 4A is a perspective view of a cross section of a dielectric waveguide using metamaterial claddings.
- FIG. 4B is a simulated distribution of the electric energy density of the waveguide of the waveguide without cladding.
- FIG. 5A shows a metamaterial fiber having a core surrounded by anisotropic cladding achieved by nanowires.
- FIG. 5A shows a metamaterial fiber having a core surrounded by anisotropic cladding achieved by nanowires.
- FIG. 5B shows the normalized simulated distribution of the electric energy density of the bare waveguide.
- FIG. 5C shows the normalized simulated distribution of the magnetic energy density of the bare waveguide.
- FIG. 5D shows the normalized simulated distribution of the electric energy density of the waveguide with anisotropic cladding.
- FIG. 5E shows the normalized simulated distribution of the magnetic energy density of the waveguide with anisotropic cladding.
- FIG. 5F shows the normalized simulated distribution of the electric energy density of the practical waveguide surrounded by nanowires.
- FIG. 5G shows the normalized simulated distribution of the magnetic energy density of the practical waveguide surrounded by nanowires.
- FIG. 6A shows a schematic view of a silicon strip waveguide according to the invention.
- FIG. 6B shows the simulation results of the normalized x-component of the electrical field for a bare waveguide.
- FIG. 6C shows the simulation results of the normalized x-component of the electric field for a transformed cladding waveguide.
- An optical waveguide having a cladding composed of all-dielectric metamaterials is provided.
- All-dielectric waveguides are useful for low-loss confinement of electromagnetic waves at optical frequencies, e.g. slot waveguides and photonic crystal waveguides.
- Slot waveguides can confine and enhance the electric field inside a sub-diffraction low-index dielectric slot between high index waveguides, which is suitable for many applications, such as nonlinear and quantum optics.
- the enhancement in the slot arises due to the continuity condition on the displacement vector at the low-index/high-index interface. However, most of the power lies outside the slot region and decays slowly.
- PIC Photonic Integrated Circuit
- the light confinement mechanism in Photonic crystal (“PhC”) waveguides is the bragg reflection of waves in the bandgap of the PhC.
- the properties of these waveguides include low radiation loss at sharp bends; but perturbing periodicity with multiple waveguides is not possible.
- the diffraction limit of light can be surpassed by the use of a class of metamaterials having a dielectric response that cannot be found in nature, but can be nanofabricated with available building blocks.
- the rules of transformation optics can be used to transform optical momentum for controlling evanescent waves. With this class of transformations, it is possible to confine light inside a subwavelength low-index dielectric rod surrounded by metamaterial claddings. This transformation can cause the propagating mode to become close to a transverse electromagnetic (“TEM”) mode.
- TEM transverse electromagnetic
- an all-dielectric metamaterial waveguide can be achieved using the Silicon-On-Insulator platform with increased power confinement in the core for dense photonic integration.
- the proposed metamaterial waveguide can dramatically decrease crosstalk between two slab waveguides at the telecommunication wavelength (i.e. 1550 nm).
- a solution can be found using the rules of transformation optics (“TO”), which state that Maxwell's equations written in a transformed coordinate system preserve their original form if the material parameters are renormalized.
- TO transformation optics
- an optical functionality can be interpreted as a distortion of a Cartesian mesh and the rules of transformation optics lead to the exact material parameters which can achieve this optical functionality.
- Such transformation optical devices have allowed control over the electromagnetic fields of propagating waves and the flow of energy for applications such as invisibility.
- the concept of transforming optical momentum can be used to control the physical property of a medium that governs whether a wave propagates or decays in the medium.
- k x ′ 2 h x 2 + k y ′ 2 h y 2 + k z ′ 2 h z 2 k 0 2
- FIG. 1 generally displays the phenomenon of refraction and reflection revisited using transformation of optical momentum. Rays of light are reflected and refracted at an interface since the mesh representing electromagnetic space has a discontinuity. FIG. 1A shows how total internal reflection can be viewed as a transformation of optical momentum. When grid sizes in the second medium become large enough, the incident ray is totally reflected and evanescently decays in the second medium.
- Electromagnetic boundary conditions require the tangential momentum and, hence, the phase to be continuous across this interface.
- the ray can be completely reflected back if the transformed momentum in the tangential direction kz1/hz exceeds the maximum possible momentum in the medium kz1/hz>k0 (as shown in FIG. 1B ).
- This causes the wave to decay away along the x-direction in region x>0.
- kz1 ⁇ k0 the condition for the possibility of total internal reflection is that the transformation should be such that hz ⁇ 1.
- FIG. 1B displays how only one component of the dielectric tensor controls the total internal reflection condition.
- the wave extends evanescently into the second medium.
- the total internal reflection is governed by the momentum transformation only in the z direction, and not the x direction.
- FIG. 1C shows a conventional waveguide based on total internal reflection. As the core size is decreased, most of the power lies outside and decays slowly in the cladding ( 20 ).
- FIG. 1D displays an embodiment of a transformed cladding waveguide. Relaxed total internal reflection ( ⁇ x ⁇ n12) preserves the conventional waveguiding mechanism; and the light decays fast in the cladding as the optical momentum in the cladding is transformed using anisotropy ( ⁇ x>>1). Thus the wave can be confined inside the core going rise to sub-diffraction optics with completely transparent media.
- the momentum transformation can be applied to surround an infinitely long glass rod with an arbitrary shaped cross sectional (A ⁇ 2 ).
- the electromagnetic grid has a finite width and, in some embodiments, needs to achieve hx,hy>>1 and hz ⁇ 1 to allow for the lowest-order mode to travel inside the glass core and bounce off by total internal reflection but simultaneously decay away rapidly causing sub-diffraction confinement of the mode (as shown in FIG. 4A ).
- This transformation also causes the longitudinal components of fields, in comparison to the transverse ones, to go zero. Indeed, the electric and magnetic fields for the transformed waveguide can be related to the untransformed ones as:
- This class of artificial media are referred to herein as “dual-anisotropic-giant-birefringent metamaterials”.
- momentum transformations unlike conventional TO applications, can be fulfilled by homogenous materials, the cladding 20 must be dual-anisotropic which is difficult to implement at optical frequencies. However, general dual-anisotropic structures can potentially be implemented at terahertz or microwave frequencies.
- FIGS. 4A and 4B display light confinement inside a low-index 2D dielectric waveguide using metamaterial claddings.
- FIG. 4A displays the confinement of a guided wave inside a transparent low index dielectric with arbitrary cross section.
- the momentum transforming cladding surrounding the core preserves total internal reflection and simultaneously leads to rapid decay of evanescent waves outside the core.
- the electric field momentum can only transform in the cladding.
- this reduced implementation can confine electric energy inside a low index dielectric.
- the simulated electric energy density of the arbitrary shaped waveguide but with an all-dielectric anisotropic cladding is shown in FIG. 4B .
- the waveguide without cladding is shown in the inset.
- the calculated mode area for the bare waveguide is about 80A0 and only 1% of the total power lies inside the core.
- the optical telecommunication wavelength i.e. 1550 nm
- the optical telecommunication wavelength using practical achievable all-dielectric metamaterials can transform the optical momentum to confine the fundamental transverse magnetic (TM) mode of a slab waveguide 30 .
- fill fraction is defined as: d Ge /( d Ge +d air ), wherein d Ge and d air are the thickness of each layer of germanium and air, respectively.
- FIG. 2A displays a plot of a normalized tangential electric filed of the TM mode for a glass slab waveguide with a size of 0.1 ⁇ surrounded by all-dielectric metamaterial cladding.
- a rapid decay of the evanescent fields is observed.
- the plots are normalized to the same input electric charge.
- the inset shows that as the anisotropy of the cladding increases the mode length decreases significantly below the diffraction limit with completely transparent media. This can be accomplished with a cladding size (width b) three times that of the core (width a).
- the inset shows that the net power in the core is also higher for the TCW as compared to conventional waveguides.
- FIG. 3A shows schematic grids for two coupled slab waveguides 30 where the cladding 20 has been transformed to allow total internal reflection but strong decay of waves in the cladding.
- a periodic multilayer combination of a high-index and low-index dielectric shows extreme effective anisotropy needed for the optical momentum transformation.
- the mesh transformation that gives rise to a cladding with low cross-talk between closely spaced waveguides can be achieved by surrounding the waveguide cores 30 with multilayer all-dielectric metamaterials 20 .
- FIG. 3B shows a comparison of coupling length (cross-talk) for conventional slab waveguides, slot waveguides and transformed cladding waveguides. It shows that the TCW improves the cross-talk by an order of magnitude and the practical multiplayer structure result is in excellent agreement with the effectively anisotropic cladding.
- the core is silicon with a center to center separation of 0.5 ⁇ between waveguides.
- Each slot-waveguide has the same net size as the core of the other waveguides; the slot size is 0.01 ⁇ and is filled with glass. If the slot size is larger or the slot index is lower, the cross talk performance is worse than that shown in FIG. 3B .
- the chart also shows that the slot waveguide cross-talk is always more than the conventional waveguide.
- a common criterion for finding coupling between two adjacent waveguides is coupling length, the length, Lc, for which the total power can be transferred from one waveguide to another one (Lc ⁇ /
- the coupling length must be much higher than the waveguides length, or in other words, ⁇ e and ⁇ o must become close to each other. Consequently, the power decays fast outside the waveguides and become negligible at the midpoint between waveguides.
- the analytically calculated coupling length for this structure is 132 ⁇ , which is one order of magnitude larger than the coupling length when the slabs are surrounded by bulk silica (6 ⁇ ). This momentum transformation also helps to increase the power confinement in the core from 25% to 45%.
- the field plots for the homogenized cladding and the practical multilayer structure show good agreement depicting the increased confinement and reduced fields in the half plane between the waveguides.
- the increased coupling length for the practical structure is 119 ⁇ in agreement with EMT calculations.
- the proposed planar metamaterial cladding can be readily fabricated using existing fabrication techniques allowing dense photonic integration and interfacing with conventional waveguide cores.
- Transformed cladding waveguides can be adopted to a silicon-on-insulator (“SOI”) platform.
- SOI silicon-on-insulator
- Two types of silicon waveguides are commonly used for a PIC design: rib waveguides with typical width in a range of 1-8 ⁇ m; and silicon strip waveguides with width in a range of 250-800 nm. Rib waveguides exhibit lower loss, but strip waveguides are relatively more compact. However, the size and possibility of dense photonic integration is restricted by the diffraction limit.
- the quasi-TE mode (x-polarized) of a strip waveguide is analogous to the TM mode of a 2D slab waveguide described previously since the y-component of the electric field is relatively negligible. Therefore the momentum in cladding can be transformed using non-magnetic metamaterials.
- FIG. 6B shows simulation results of the normalized x-component of the electric field for the bare waveguide.
- FIG. 6C shows simulation results of the normalized x-component of the electric field for the transformed cladding waveguide.
- the Transformed Cladding Waveguides as disclosed herein can offer a major advantage of propagation length and low power dissipation over any plasmonic approach and decreased cross-talk when compared to slot waveguides or photonic crystals.
- the concept of transforming optical momentum is used to control evanescent waves.
- the reduced mode area and all-dielectric implementation provide a useful platform for enhancing nonlinear and quantum phenomena as well as optical forces.
- the practical all-dielectric metamaterial cladding introduced herein can be implemented using readily available lossless semiconductor building blocks at 1.55 ⁇ m.
- the TCW ridge waveguide described herein can use the common SOI platform, and furthermore as the core of the waveguide is not changed, inter-connects with widely used waveguide structures are possible. All-dielectric magnetism can be used to provide a dual anisotropic implementation, allowing the propagating mode in conventional fibers to reach ideal quasi-TEM behavior.
- Matter waves are also governed by the wave equation. This implies the approach of reduction of tunneling of electromagnetic waves can be applied to electron waves. The approach can be used to design anisotropic effective masses and reduce the tunneling of electrons.
- the devices according to the invention can be utilized for resonators and design of active devices.
- the devices according to the invention can be utilized to increase the spontaneous emission of light emitting devices since the light confinement using anisotropy leads to a higher overlap of field and emitter.
- the devices according to the invention can be utilized to increase the nonlinearity if the core is nonlinear.
- the metamaterial cladding 20 may include germanium nanorods embedded in porous silica surrounding a silica rod core 30 .
- FIGS. 5B to 5G show a normalized simulated distribution of the electric ( 5 A, 5 B and 5 F) and magnetic ( 5 C, 5 E and 5 G) energy density of the waveguide when the core diameter is 0.15 ⁇ and the germanium fill fraction is 62.5%.
- FIGS. 5B and 5C display the electric and magnetic energy density of a bare waveguide.
- the fraction of power inside the core to the total power ( ⁇ ) is 3% and the mode area is 43( ⁇ /2ncore)2.
- the calculated ⁇ , mode area, and effective index are 35%, 1.85 ( ⁇ /2ncore)2, and 2.13 respectively.
- FIGS. 5F and 5G display the electric and magnetic density of the practical waveguide surrounded by nanowires which achieves the required anisotropy. According to effective theory.
- the simulation domain length in the y direction was only ⁇ /40, terminated to magnetic boundary conditions to model infinite width for the slab waveguides.
- the open boundaries in x directions were assigned one away from slab waveguides.
- the propagation constants were derived from port information 1D results, and are in good agreement with analytical calculations.
- the simulations were made to converge with a maximum residual energy inside the calculation domain of 10-6 and 10-3 for time domain and frequency domain simulations, respectively.
- Germanium was used as the high-index dielectric material in the waveguide cladding strata.
- Other high-index dielectric materials such as Silicon and Titanium Dioxide (TiO2), as well as other materials having similar physical properties, as known to those skilled in the art, can be used with similar results.
- Silica has been used as the low-index dielectric material in the waveguide cladding strata in addition to air.
- Other low-index dielectric materials such as porous Silica and other materials having similar physical properties as well known to those skilled in the art, can be used with similar results.
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Abstract
Description
wherein the coordinate transformation is characterized by the Jacobian matrix diag [hx,hy,hz], the transformed wavevector {right arrow over (k)}=[kx′,ky′,kz′] and (k0=2π/λ) k0=ω/c is the free space wavevector. The optical momentum transformation in comparison with the dispersion relation for vacuum is found to be kx′=hxkx, ky′=hyky, and kz′=hzkz. Note that although constitutive parameters are anisotropic in general, the momentum transformation for all waves are described by this quadratic (not quartic) formula. This is a consequence of
a condition defined herein as dual electric and magnetic anisotropy.
and due to the large confinement factor (γ), the longitudinal field components become negligible. Thus, the transformed propagating mode is a quasi-TEM mode, and in contrast to conventional waveguides at low-frequencies, it does not need two reflectors or perfect conductor at boundaries.
d Ge/(d Ge +d air),
wherein dGe and dair are the thickness of each layer of germanium and air, respectively.
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